源于中间偃麦草的抗条锈基因YrCH223的遗传分析及SSR定位

CH223是一个衍生于中间偃麦草的多抗性小偃麦种质系,通过感病的小麦品种与八倍体小偃麦TAI7047杂交、回交选育而成。抗性鉴定表明,CH223对我国当前小麦条锈病的流行小种CYR32,CYR33均有良好抗性。利用CH223与感病品种(系)的F2,F2∶3和BC1抗性分离群体进行抗性遗传分析,发现其条锈病抗性来自中间偃麦草,且由1对显性基因控制,暂时命名为YrCH223。用CYR32对来自台长29×CH223的221个F2植株进行接种鉴定,并构建抗、感DNA池。共筛选738对SSR引物,发现5对共显性SSR标记与抗病基因连锁,位置顺序为:Xgwm540-Xbarc1096-YrCH223-Xwmc47-Xwmc310-Xgpw7272,遗传距离分别为21.9,8.0,7.2,12.5,11.3 cM。进一步利用中国春缺体-四体和双端体材料扩增鉴定,将YrCH223定位于小麦4B染色体的长臂上(4BL)。经F2∶3群体验证,5个标记与YrCH223连锁。迄今为止,在4BL上未发现有公开报道的抗小麦条锈病基因。因此,基于抗病基因所在的染色体位置与来源,推断YrCH223是一个新的抗条锈病基因。     

中国小麦品种兰天9号慢叶锈性QTL分析

【目的】由小麦叶锈菌（Puccinia triticina）引起的小麦叶锈病是影响小麦稳产、高产的一种重要真菌病害。目前防治小麦叶锈病最经济、安全、有效的方法是种植抗病品种。中国小麦品种兰天9号苗期对大多数叶锈菌小种表现感病,成株期对小麦叶锈菌则表现为明显的慢锈性。研究旨在分析中国小麦品种兰天9号的成株抗叶锈性,发掘其中含有的QTL,并利用分子标记进行定位,为小麦分子育种提供理论基础。【方法】利用抗病亲本兰天9号和感病亲本辉县红杂交获得到197个家系的F_2:3群体,2011-2014年连续3年在河北保定种植,并利用3个叶锈菌生理小种混合菌种（THTT、THTS、THTQ）进行田间接菌,小麦成株期调查最终发病严重度,获得表型数据。利用1 232对SSR标记对兰天9号、辉县红以及F_2:3群体进行基因检测,获得基因型数据。结合表型数据和基因型数据,利用Map Manager QTXb20创建连锁图、QTL Icimapping 3.2软件进行抗叶锈病QTL分析。【结果】检测到5个QTL,其中位于2B染色体上的QTL暂命名为QLr.hbau-2BS,在连续两年的数据结果中都被检测到,解释的遗传变异分别为6.0%和9.1%;标记区间分别为Xbarc55-Xgwm148和Xgwm429-Xwmc154;LOD值分别为2.6和3.46;加性效应分别为-6.1和-8.7;显性效应分别为3.03和3.4。1B染色体上1个QTL暂命名为QLr.hbau-1BL.2,连续两年被检测到,解释的遗传变异分别为7.7%和10.7%;标记区间为Xwmc766-Xbarc269;LOD值分别为2.5和3.1;加性效应分别为-1.0和-1.1;显性效应分别为-13.0和-14.9。其他3个QTL只在一个年份被检测到,1B染色体上暂命名为QLr.hbau-1BL.1、4B上暂命名为QLr.hbau-4BS、3A上暂命名为QLr.hbau-3A,均在2011-2012年度检测到,解释的遗传变异分别为11.7%、8.5%、5.6%;标记区间分别为Xbarc80-Xwmc728、Xgwm495-Xwmc652和Xgwm161-Xbarc86;LOD值分别为5.1、4.0和2.8;加性效应分别为6.5、-5.5和-3.1;显性效应分别为-6.5、6.2和6.6。QLr.hbau-1BL.1来源于感病亲本辉县红,其余4个QTL来源于兰天9号。【结论】结合田间表型数据和基因型数据,检测到位于1B、2B、3A、4B染色体上5个控制成株抗叶锈的QTL。     

小麦RIL群体遗传连锁图谱的构建及其多态性分析

以普通小麦重组近交系(recombinant inbred lines,RIL)‘Q9086×陇鉴19’为作图群体,利用SSR标记构建小麦遗传连锁图谱.结果表明:通过选用2 187对SSR引物筛选出RIL群体双亲表现多态性的引物共405对,多态性频率为18.52%.不同类型SSR标记多态性频率从小到大依次为Xpsp(4.4%)相似文献   

Molecular mapping of YrTZ2, a stripe rust resistance gene in wild emmer accession TZ-2 and its comparative analyses with Aegilops tauschii

Wheat stripe rust, caused by Puccinia striiformis f. sp. tritici (Pst), is a devastating disease that can cause severe yield losses. Identification and utilization of stripe rust resistance genes are essential for effective breeding against the disease. Wild emmer accession TZ-2, originally collected from Mount Hermon, Israel, confers near-immunity resistance against several prevailing Pst races in China. A set of 200 F_6:7 recombinant inbred lines (RILs) derived from a cross between susceptible durum wheat cultivar Langdon and TZ-2 was used for stripe rust evaluation. Genetic analysis indicated that the stripe rust resistance of TZ-2 to Pst race CYR34 was controlled by a single dominant gene, temporarily designated YrTZ2. Through bulked segregant analysis (BSA) with SSR markers, YrTZ2 was located on chromosome arm 1BS flanked by Xwmc230 and Xgwm413 with genetic distance of 0.8 cM (distal) and 0.3 cM (proximal), respectively. By applying wheat 90K iSelect SNP genotyping assay, 11 polymorphic loci (consisting of 250 SNP markers) closely linked to YrTZ2 were identified. YrTZ2 was further delimited into a 0.8-cM genetic interval between SNP marker IWB19368 and SSR marker Xgwm413, and co-segregated with SNP marker IWB28744 (co-segregated with 28 SNP). Comparative genomics analyses revealed high level of collinearity between the YrTZ2 genomic region and the orthologous region of Aegilops tauschii 1DS. The genomic region between loci IWB19368 and IWB31649 harboring YrTZ2 is orthologous to a 24.5-Mb genomic region between AT1D0112 and AT1D0150, spanning 15 contigs on chromosome 1DS. The genetic and comparative maps of YrTZ2 provide a framework for map-based cloning and marker-assisted selection of YrTZ2.     

Molecular mapping of stripe rust resistance gene YrH9017 in wheat-Psathyrostachys huashanica introgression line H9017-14-16-5-3

Several new stripe rust pathogen races emerged in the wheat growing regions of China in recent years. These races were virulent to most of the designated wheat seedling resistance genes. Thus, it is necessary and worthwhile to identify new valuable resistant materials for the sake of diversifying resistant sources, pyramiding different resistance genes and achieving durable resistance. Here, we identified the resistance gene, temporarily designated as YrH9017, in wheat-Psathyrostachys huashanica introgression line H9017-14-16-5-3. A total of 146 F₂ plants and their derived F_2:3 families in a cross of Mingxian 169 and H9017-14-16-5-3 were used to evaluate seedling stripe rust response and as a mapping population. Finally, we constructed a genetic map including eight simple sequence repeat (SSR) markers and expressed sequence tag (EST) markers. YrH9017 was located on the long arm of chromosome 2A and closely linked with two EST-sequence tagged site (EST-STS) markers BG604577 and BE471201 at 1.3 and 1.8 cM distance, respectively. The two closest markers could be used for marker-assisted selection of YrH9017 in breeding.     

小麦白粉病抗病新基因PmHNK的遗传分析和分子标记定位

 【目的】周98165对河南省当前流行白粉菌生理小种具有较好的抗性,并且综合农艺性状优良。明确其抗白粉病基因及遗传特性,筛选与其紧密连锁的分子标记,为抗白粉病育种提供抗源和理论支撑。【方法】将周 98165与中国春杂交、自交、测交,对双亲及其杂交后代进行苗期鉴定,用小麦白粉病菌08B1进行遗传分析,利用SSR、EST-SSR技术对双亲及抗感池进行筛选和电泳分析,并结合中国春缺四体材料进行染色体定位。【结果】周98165对3个白粉菌高毒力小种抗性良好,其抗病性受1对显性核基因控制,将该基因暂命名为PmHNK。筛选了与PmHNK 连锁的5个微卫星标记,在遗传图谱上的顺序为Xbarc77、Xgwm547、Xwmc326、Xgwm299、PmHNK、Xgwm108,Xgwm299和Xgwm108分别为PmHNK两侧距离最近的标记,图距分别为4.2 cM、5.6 cM,最远标记Xbarc77与PmHNK图距为10.6 cM,并将PmHNK 定位于3BL。【结论】抗病鉴定、遗传分析结合分子标记分析结果表明,PmHNK是一个白粉病抗病新基因。     

Inheritance and Molecular Mapping of Stripe Rust Resistance Gene Yr88375 in Chinese Wheat Line Zhongliang 88375

Stripe rust is one of the most important diseases of wheat worldwide. Inheritance of stripe rust resistance and mapping of resistance gene with simple sequence repeat （SSR） markers are studied to formulate efficient strategies for breeding cultivars resistant to stripe rust. Zhongliang 88375, a common wheat line, is highly resistant to all three rusts of wheat in China. The gene conferring rust disease was deduced originating from Elytrigia intermedium. Genetic analysis of Zhongliang 88375 indicated that the resistance to PST race CYR31 was controlled by a single dominant gene, temporarily designated as Yr88375. To molecular map Yr88375, a F2 segregating population consisting of 163 individuals was constructed on the basis of the hybridization between Zhongliang 88375 and a susceptible wheat line Mingxian 169; 320 SSR primer pairs were used for analyzing the genetic linkage relation. Six SSR markers, Xgwm335, Xwmc289, Xwmc810, Xgdmll6, Xbarc59, and Xwmc783, are linked to Yr88375 as they were all located on chromosome 5BL Yr88375 was also located on that chromosome arm, closely linked to Xgdmll6 and Xwmc810 with genetic distances of 3.1 and 3.9 cM, respectively. The furthest marker Xwmc783 was 13.5 cM to Yr88375. Hence, pedigree analysis of Zhongliang 88375 combined with SSR markers supports the conclusion that the highly resistance gene Yr88375 derived from Elytrigia intermedium is a novel gene for resistance to stripe rust in wheat. It could play an important role in wheat breeding programs for stripe rust resistance.     

ARz×扬麦158群体对小麦抗赤霉病性的QTL分析

通过单粒传法构建了含130个家系的AR z×扬麦158 F6∶7重组自交系群体(R IL),并采用田间病圃自然发病和喷洒悬浮孢子液两种方法对该群体进行赤霉病田间抗性鉴定;利用SSR标记对群体中控制抗赤霉病性的QTL进行定位分析。结果表明:群体中各家系的病情指数在所有试验中都存在很大的变异,在2002年、2003年和2005年其变异幅度分别为20.0%~80.0%,10.6%~74.6%和33.2%~89.0%;不同年份间的病情指数具有中等程度的相关性,且都达到了极显著水平(P<0.000 5);Xgwm114、Xgwm296、Xgwm111.2等15个SSR标记位点与群体抗赤霉病性显著相关,这些位点分别位于2DL、3BL和7DL等染色体上;经区间作图分析发现位于染色体7D上的Xwm c 94~Xwm c273.2区间存在一个抗赤霉病QTL,它在3年试验中的LOD值分别为1.5、2.6和2.0,可解释病情指数变异率的5.8%、8.7%和6.7%,Xgwm114是与该抗赤霉病QTL紧密连锁的标记位点,位于该抗性QTL的峰值区域。     

两个新的水稻叶色突变体形态结构与遗传定位研究

【目的】对2个新的水稻叶色突变体进行形态结构与遗传分析,并且初步定位这2个突变基因。【方法】在水稻育种材料中分别发现了一株白色条纹叶突变体和一株黄叶突变体,经多代自交已形成稳定的突变系。对突变体的主要形态特征与叶绿素组分等进行分析,观察叶绿体的超微结构,并以这2个突变系杂交产生的F2群体作为定位群体,应用SSR标记对突变基因进行初定位。【结果】与其野生型相比,白色条纹叶突变体的单株穗数减少12.86%,生育期延长11.27%,黄色叶突变体的株高降低31.08%,千粒重减少14.55%,生育期延长17.86%,并且2种突变体的叶绿素含量都显著低于其野生型。电镜观察结果表明：2种突变体的类囊体结构异常,与野生型水稻相比,黄色叶突变体的类囊体片层数变少,白色条纹叶中条纹部分的类囊体片层结构几乎消失,正常绿色部分的类囊体结构没有变化。遗传分析表明：这2种突变性状均受1对隐性核基因控制,位于不同染色体上,将突变基因暂时命名为st9(t)(stripe)、chl12(t) (Chlorophyll-deficit)。将st9(t)定位到第一染色体短臂最末端,与分子标记RM1331相距9.6 cM,且与标记RM3252等共分离;将chl12(t)定位到第三染色体短臂,与分子标记RM411、RM8208之间的遗传距离分别是1.2、5.1 cM。【结论】发现了2个叶色突变新基因,为下一步的基因克隆与功能分析奠定了基础。     

簇毛麦易位系V9125-2抗条锈基因YrWV的遗传分析和SSR分子标记

[目的]对高抗条锈病的簇毛麦易位系V9125-2进行研究,明确其抗病性遗传特点,并对其抗条锈病基因定位,为选育优质抗源材料提供依据.[方法]采用中国当前流行的7个条锈菌生理小种CYR29、CYR30、CYR31、CYR32、CYR33以及Su11-4、Su11-11对簇毛麦易位系V9125-2和铭贤169的杂交后代进行...     

小麦条锈菌生理小种国际鉴别寄主Spaldings Prolific中抗条锈病基因YrSpP的微卫星标记

 Spaldings Prolific是国际小麦条锈菌鉴别寄主和国内外重要抗源。以含有小麦抗条锈病基因YrSpP的近等基因系Taichung29*6/YrSpP及其轮回亲本Taichung29为材料， 用目的基因所在2B染色体上88对微卫星引物对其基因组DNA进行PCR扩增和电泳分析，发现用WMC441引物在近等基因系与轮回亲本间稳定扩增出特异性DNA片段。经F2代群体162个抗、感单株检测证实，该片段位点与抗条锈病基因YrSpP连锁，遗传距离为10.9 cM，确定WMC441为抗条锈病基因YrSpP的标记，并可用于该基因的检测和辅助选择。     

小麦品系西农1163-4抗叶锈病基因的遗传分析和分子作图#br#

【目的】小麦品系西农1163-4高抗小麦叶锈、条锈和白粉病,综合农艺性状良好。明确该小麦品系中所含的抗叶锈病基因及遗传特点,找到与其紧密连锁的分子标记,有利于抗病基因利用和培育抗病新品种。【方法】将西农1163-4与感病品种Thatcher杂交,获得F1、F2代群体,利用中国叶锈菌优势小种THTT进行苗期抗性鉴定和抗性遗传分析;采用SSR技术对西农1163-4所携带的抗叶锈基因进行分子标记研究,共筛选了1 273对SSR引物。【结果】小麦品系西农1163-4对多个叶锈菌小种具有良好的抗病性,对THTT的抗性是由1个显性基因控制,该基因暂命名为LrXi。获得了与LrXi紧密连锁的3个微卫星分子标记Xbarc8、Xgwm582、Xwmc269和1个STS标记(ω-secali/Glu-B3),将LrXi定位于小麦1BL染色体上。距离最近的2个微卫星位点是Xgwm582、Xbarc8,与抗叶锈基因间的遗传距离分别为2.3 cM和3.2 cM。【结论】LrXi位于1BL染色体,抗叶锈表现不同于所有已知抗叶锈病基因,该基因的发现将有利于丰富中国抗叶锈病基因资源,为培育持久抗病品种奠定基础。     

小麦单株产量及其相关性状的全基因组QTL分析

探索和鉴定调控小麦产量因子的基因位点有助于产量的遗传改良。以安农0711/烟农19 BC1F2回交群体(680个家系)为供试材料,单粒播种,于黄熟期测定单株有效穗数,收获后测定穗粒数、千粒重及单株产量。利用完备区间作图法对上述单株产量及其相关性状进行全基因组QTL定位。结果表明,控制千粒重的QTL有3个,主要分布在染色体1D(2个)和4B(1个)上,分别位于标记区间Xcfd27-Xwmc432,Xwmc432-Xcfd61和Xwmc89-Xwmc48;控制单株产量和单株有效穗数的QTL均各有2个,分别位于染色体1A和5D的相同区间Xwmc312-Xwmc120和Xgwm271-Xcfd18;没有检测到控制穗粒数的QTL位点。     

小麦品系西农1163-4抗叶锈病基因的遗传分析和分子作图

【目的】小麦品系西农1163-4高抗小麦叶锈、条锈和白粉病,综合农艺性状良好。明确该小麦品系中所含的抗叶锈病基因及遗传特点,找到与其紧密连锁的分子标记,有利于抗病基因利用和培育抗病新品种。【方法】将西农1163-4与感病品种Thatcher杂交,获得F1、F2代群体,利用中国叶锈菌优势小种THTT进行苗期抗性鉴定和抗性遗传分析;采用SSR技术对西农1163-4所携带的抗叶锈基因进行分子标记研究,共筛选了1 273对SSR引物。【结果】小麦品系西农1163-4对多个叶锈菌小种具有良好的抗病性,对THTT的抗性是由1个显性基因控制,该基因暂命名为LrXi。获得了与LrXi紧密连锁的3个微卫星分子标记Xbarc8、Xgwm582、Xwmc269和1个STS标记(ω-secali/Glu-B3),将LrXi定位于小麦1BL染色体上。距离最近的2个微卫星位点是Xgwm582、Xbarc8,与抗叶锈基因间的遗传距离分别为2.3 cM和3.2 cM。【结论】LrXi位于1BL染色体,抗叶锈表现不同于所有已知抗叶锈病基因,该基因的发现将有利于丰富中国抗叶锈病基因资源,为培育持久抗病品种奠定基础。     

Canopy morphological changes and water use efficiency in winter wheat under different irrigation treatments

Water is a key limiting factor in agriculture. Water resource shortages have become a serious threat to global food security. The development of water-saving irrigation techniques based on crop requirements is an important strategy to resolve water scarcity in arid and semi-arid regions. In this study, field experiments with winter wheat were performed at Wuqiao Experiment Station, China Agricultural University in two growing seasons in 2013–2015 to help develop such techniques. Three irrigation treatments were tested: no-irrigation(i.e., no water applied after sowing), limited-irrigation(i.e., 60 mm of water applied at jointing), and sufficient-irrigation(i.e., a total of 180 mm of water applied with 60 mm at turning green, jointing and anthesis stages, respectively). Leaf area index(LAI), light transmittance(LT), leaf angle(LA), transpiration rate(Tr), specific leaf weight, water use efficiency(WUE), and grain yield of winter wheat were measured. The highest WUE of wheat in the irrigated treatments was found under limited-irrigation and grain yield was only reduced by a small amount in this treatment compared to the sufficient irrigation treatment. The LAI and LA of wheat plants was lower under limited irrigation than sufficient irrigation, but canopy LT was greater. Moreover, the specific leaf weight of winter wheat was significantly lower under sufficient than limited irrigation conditions, while the leaf Tr was significantly higher. Correlation analysis showed that the increased LAI was associated with an increase in the leaf Tr, but the specific leaf weight had the opposite relationship with transpiration. Optimum WUE occurred over a reasonable range in leaf Tr. In conclusion, reduced irrigation can optimize wheat canopies and regulate water consumption, with only small reductions in final yield, ultimately leading to higher wheat WUE and water saving in arid and semi-arid regions.     

小麦抗赤霉病基因的SSR标记筛选

以望水白／安农8455的一粒传(SSD)产生的重组自交系群体为材料，对抗赤霉病QTLs的微卫星(SSR)标记进行筛选。结果表明：75个SSR引物在两亲本间有多态性，多态性达32．47％，其中5个SSR引物在2个亲本和抗、感池间均具相同的多态性。经标记-抗性关联分析和区间作图，引物Xgwm512、Xgwm114、Xgwm340和Xgwm3经2年关联分析F值均极显著，LOD值均大于阈值2．4，表明在2AS、3BL和3DL各有1个抗赤霉病QTL位点存在。区间作图分析表明，3BL上的1个QTL位于Xgwm340和Xgwm114之间，距Xgwm340位点约10cM，能够解释20．45％的赤霉病抗性变异。     

Identification of AFLP Markers Linked to Lr19 Resistance to Wheat Leaf Rust

AFLP analyses were carried out on Thatcher, 23 near-isogenic lines and F2 generation of TcLrl9 × Thatcher, to develop molecular markers for gene Lr19 resistance to wheat leaf rust. Seven markers linked to Lr19 resistance trait were obtained,which were P-AGT/M-GAG289 bp (3.3 cM), P-ACA/M-GGT102 bp (4.1 cM), P-ACA/M-GGT106 bp (4.1 cM), P-AAC/M-CAG123 bp(4.9 cM), P-AAC/M-GGT203 bp (5.0 cM), P-ACA/M-GGT290 bp (5.7 cM), and P-ATC/M-GAG293 bp (9.6 cM). All of these specific fragments were isolated from the polyacrylamide gels, reamplified, cloned, and sequenced. The research may facilitate genetic mapping, physical mapping, and the eventual cloning of Lr19.     

分子标记在小麦抗赤霉病辅助育种中的应用

本研究探讨了与小麦抗赤霉病QTL紧密连锁的SSR标记Xbarc 133、Xgwm 493、Xgwm 533 a在育种早代材料中辅助选择的有效性。结果显示:虽然不同的育种世代具有最高选择效率的标记或标记组合不一样,但是Xbarc 133、Xgwm 493、Xgwm 533 a三标记一起的选择效率在F3和F4的筛选中均较高。建议小麦的抗赤霉病分子标记辅助育种选用Xbarc 133、Xgwm 493、Xgwm 533 a三标记一起进行筛选。     

CIMMYT小麦PBW343和Muu中条锈和叶锈成株抗性QTL分析

为发掘CIMMYT小麦品种PBW343和Muu中条锈和叶锈成株抗性基因,以PBW343与Muu杂交的146个F6代重组自交系为材料,种植于田间调查鉴定,并利用31个SSR标记、16个EST标记和502个DArT(Di-versity Arrays Technology)标记构建连锁图,采用复合区间作图法进行小麦条锈病和叶锈病的成株抗性QTL分析,发现了2个控制小麦抗条锈病和1个控制小麦抗叶锈病的QTL,分别位于2AL、2BL和5BL上,解释8.89%,10.81%和12.82%的表型变异,3个QTL均来自小麦品种Muu。这2个小麦抗条锈QTL和1个抗叶锈QTL的发掘,将为小麦抗病育种提供理论和技术支持。     

源于叙利亚小麦ICA31抗条锈病基因分析及分子标记研究

遗传分析表明,小麦材料ICA31携带一个显性抗条锈病基因,对流行的优势条锈菌小种条中30,31,32免疫;据等位性测定,ICA31抗条锈基因与已知抗锈基因Yr5、Yr10、Yr15不等位;从抗源的系谱分析,该基因来源于叙利亚普通小麦品系叙18;利用微卫星标记和分组分析(BSA)法,筛选到与该抗条锈病基因(Yr-Syria)紧密连锁的SSR标记WMS11-193;对F2分离群体142个单株分析结果表明,该抗条锈病基因(Yr-Syria)与WMS11-193间遗传距离为2.1cM;将Yr-Syria定位于小麦1BS上;为该基因进行抗条锈小麦分子辅助育种打下基础。